Authentication is the process for identify the user authorized or not. The identity contains mainly the username and passwords for verifying the two entities. The authentication information\'s are stored in the form encryption in a device which is properly registered in the server. At the time of authentication process perform between user and server the intruder can eves-dropping the communication channel and login into the system by an authorized user. To overcome this optimal strong password authentication (OSPA) protocol uses the multiple hash operation the time of authentication for the users. The server chooses the hash function only at the time of user request for the login process. So the intruder cannot know the information which is transferred at the time of authentication process.

The OSPA can improve the authentication process for obtaining mutual communication between user and server. The authentication information will not know to the intruder. So the multiple hash function obtains the secure authentication information process. The OSPA protect information of the user & server and protect from the guessing attack. The guessing attack prevention performs by the server using the multiple hash function & USB Stick.

In this work, we describe a simple and efficient construction of a large subset S of F_p, where p is a prime, such that the set A(S) for any non-identity affine map A over F_p has small intersection with S.

Such sets, called affine-evasive sets, were defined and constructed in~\\cite{ADL14} as the central step in the construction of non-malleable codes against affine tampering over F_p, for a prime p. This was then used to obtain efficient non-malleable codes against split-state tampering.

Our result resolves one of the two main open questions in~\\cite{ADL14}. It improves the rate of non-malleable codes against affine tampering over F_p from log log p to a constant, and consequently the rate for non-malleable codes against split-state tampering for n-bit messages is improved from n^6 log^7 n to n^6.

We present explicit optimal binary pebbling algorithms for reversing one-way hash chains. For a hash chain of length $2^k$, the number of hashes performed per output round is at most $\\lceil \\tfrac{k}{2}\\rceil$, whereas the number of hash values stored throughout is at most $k$. This is optimal for binary pebbling algorithms characterized by the property that the midpoint of the hash chain is computed just once and stored until it is output, and that this property applies recursively to both halves of the hash chain.

We develop a framework for easy comparison of explicit binary pebbling algorithms, including simple speed-1 binary pebbles, Jakobsson\'s binary speed-2 pebbles, and our optimal binary pebbles. Explicit schedules describe for each pebble exactly how many hashes need to be performed in each round. The optimal schedule exhibits a nice recursive structure, which allows fully optimized implementations that can readily be deployed. In particular, we develop in-place implementations with minimal storage overhead (essentially, storing only hash values), and fast implementations with minimal computational overhead.

In this paper we propose a new framework of cryptocurrency system. The major parts what we have changed include removing the bloated history transactions from data synchronization, no mining, no blockchain, it\'s environmentally friendly, no checkpoint, no exchange hub needed, it\'s purely decentralized and purely based on proof of stake. The logic is very simple and intuitive, 51% stakes talk. A new data synchronization mechanism named \"Converged Consensus\" is proposed to ensure the system reaches a consistent distributed consensus. We think the famous blockchain mechanism based on PoW is no longer an essential element of a cryptocurrency system. In aspect of security, we propose TILP & SSS strategies to secure our system.

Machine learning classification is used in numerous settings nowadays, such as medical or genomics predictions, spam detection, face recognition, and financial predictions. Due to privacy concerns in some of these applications, it is important that the data and the classifier remain confidential.

In this work, we construct three major classification protocols that satisfy this privacy constraint: hyperplane decision, Na\\\"ive Bayes, and decision trees. These protocols may also be combined with AdaBoost. They rely on a library of building blocks for constructing classifiers securely, and we demonstrate the versatility of this library by constructing a face detection classifier.

Our protocols are efficient, taking milliseconds to a few seconds to perform a classification when running on real medical datasets.

Template Attacks are widely accepted to be the most powerful side-channel attacks from an information theoretic point of view. For classical Template Attacks, several papers suggested that one should not choose more than one point as the interesting point per clock cycle when he conducts Template Attacks. Disobeying this constraint leads to poorer classification performance even if a higher number of interesting points is chosen. A more systematic approach, which relies on the data variability, is to choose the interesting points based on principal component analysis (PCA). In this paper, we present a new way of conducting Template Attacks when one uses more than one point as the interesting point per clock cycle. This new way has better classification performance compared with classical Template Attacks and PCA-based Template Attacks. Moreover, the computational price of the new way is low and practical. Therefore, we suggest that one should use this new way to better understand practical threats of Template Attacks when one want to use more than one point as the interesting point per clock cycle.

We give an optimal-size representation for the elements of the trace zero subgroup of the Picard group of an elliptic or hyperelliptic curve of any genus, with respect to a field extension of any prime degree. The representation is via the coefficients of a rational function, and it is compatible with scalar multiplication of points. We provide efficient compression and decompression algorithms, and complement them with implementation results. We discuss in detail the practically relevant cases of small genus and extension degree, and compare with the other known compression methods.

In this paper, we propose a new lightweight block cipher called FeW which encrypts 64-bit plaintext using key size 80/128 bits and produces 64-bit ciphertext. FeW is a software oriented design with the aim of achieving high efficiency in software based environments. We use a mix of Feistel and generalised Feistel structures (referred as Feistel-M structure hereinafter) to enhance the security of our design against basic cryptanalytic attacks like differential, linear, impossible differential and zero correlation attacks. Security analysis of this scheme proves its strength against present day cryptanalytic attacks.

One approach towards basing public-key encryption schemes on weak and credible assumptions is to build ``stronger\'\' or more general schemes generically from ``weaker\'\' or more restricted schemes. One particular line of work in this context, which has been initiated by Myers and Shelat (FOCS \'09) and continued by Hohenberger, Lewko, and Waters (Eurocrypt \'12), is to build a multi-bit chosen-ciphertext (CCA) secure public-key encryption scheme from a single-bit CCA-secure one. While their approaches achieve the desired goal, it is fair to say that the employed techniques are complicated and that the resulting ciphertext lengths are impractical.

We propose a completely different and surprisingly simple approach to solving this problem. While it is well-known that encrypting each bit of a plaintext string independently is insecure---the resulting scheme is malleable---we show that applying a suitable non-malleable code (Dziembowski et al., ICS \'10) to the plaintext and subsequently encrypting the resulting codeword bit-by-bit results in a secure scheme. To the best of our knowledge, our result is the first application of non-malleable codes in a context other than memory tampering.

The original notion of non-malleability is, however, not sufficient. We therefore prove that (a simplified version of) the code of Dziembowski et al.\\ is actually continuously non-malleable (Faust et al., TCC \'14). Then, we show that this notion is sufficient for our application. Since continuously non-malleable codes require to keep a single bit of (not necessarily secret) state in the decoding, the decryption of our scheme also has to keep this state. This slight generalization of the traditional formalization of public-key encryption schemes seems appropriate for applications. Compared to the previous approaches, our technique leads to conceptually simpler and more efficient schemes.

PANDA is a family of authenticated ciphers submitted to CARSAR, which consists of two ciphers: PANDA-s and PANDA-b. In this work we present a

state recovery attack against PANDA-s with time complexity about $2^{41}$ under the known-plaintext-attack model, which needs 137 pairs of known plaintext/ciphertext and about 2GB memories. Our attack is practical in a small workstation. Based on the above attack, we further deduce a forgery attack against PANDA-s, which can forge a legal ciphertext $(C,T)$ of an arbitrary plaintext $P$. The results show that PANDA-s is insecure.

user account, the legitimate password is stored with several honeywords in order to sense impersonation. If honeywords are selected properly, an adversary who steals a file of hashed passwords cannot be sure if it is the real password or a honeyword for any account. Moreover, entering with a honeyword to login will trigger an alarm notifying the administrator about a password file breach. At the expense of increasing storage requirement by 20 times, the authors introduce a simple and effective solution to detection of password file disclosure events. In this study, we scrutinize the honeyword system and present some remarks to highlight possible weak points. Also, we suggest an alternative approach that selects honeywords from existing user passwords in the system to provide

realistic honeywords - a perfectly flat honeyword generation method - and also to reduce storage cost of the honeyword scheme.